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LC Resonance circuits

The LC circuit

Design a parallel LC resonant circuit with a resonant frequency between 50-200 kHz. use [math]L[/math] = 10 - 100 [math]\mu H[/math], R = 1k [math]\Omega[/math]

I choose the following values for [math]\mbox{L}[/math] and [math]\mbox{C}[/math]:

So the resonance frequency is

And

Construct the LC circuit using a non-polar capacitor

Measure the Gain as a function of frequency. (25 pnts)

Compare the measured and theoretical values of the resonance frequency ([math]\omega_{L}[/math]) (10 pnts)

Let's plot the data from table above:

And let's zoom the graph above at resonance frequency:

So the experimentally measured resonance frequency is

[math]f = 27.7\ \mbox{kHz}[/math]

And the predicted value of resonance frequency is

[math]f = 27.4\ \mbox{kHz}[/math]

The error is:

[math]Error = \left| \frac{f_{exp} - f_{theor}}{f_{theor}} \right| = \left| \frac{27.7 - 27.4}{27.4} \right|= 1.09\ %[/math]

The error is small so I was lucky

Questions

1.Is there a value of [math]R[/math] in which [math]V_{out} \approx V_{in}[/math] at resonance. What is the value?(5 pnts)

Revision as of 22:27, 3 February 2011 (view source) Shaproma (talk \| contribs) (→‎Compare the measured and theoretical values of the resonance frequency (\omega_{L}) (10 pnts)) ← Older edit		Revision as of 22:27, 3 February 2011 (view source) Shaproma (talk \| contribs) (→‎Compare the measured and theoretical values of the resonance frequency (\omega_{L}) (10 pnts)) Newer edit →
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−	Let's ~~the~~ plot the data from table above:	+	Let's plot the data from table above:

	[[File:L5 LC circuit.png \| 800 px]]		[[File:L5 LC circuit.png \| 800 px]]

Difference between revisions of "Lab 5 RS"

Revision as of 22:27, 3 February 2011

Contents

The LC circuit

Design a parallel LC resonant circuit with a resonant frequency between 50-200 kHz. use [math]L[/math] = 10 - 100 [math]\mu H[/math], R = 1k [math]\Omega[/math]

Construct the LC circuit using a non-polar capacitor

Measure the Gain as a function of frequency. (25 pnts)

Compare the measured and theoretical values of the resonance frequency ([math]\omega_{L}[/math]) (10 pnts)

Questions

The RLC cicuit

Design and construct a series LRC circuit

Measure and Graph the Gain as a function of the oscillating input voltage frequency. (25 pnts)

Measure and Graph the Phase Shift as a function of the oscillating input voltage frequency. (25 pnts)

Questions

What is the current [math]I[/math] at resonance? (5 pnts)

What is the current as [math]\nu \rightarrow \infty[/math]? (5 pnts)

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Difference between revisions of "Lab 5 RS"

Revision as of 22:27, 3 February 2011

The LC circuit

Design a parallel LC resonant circuit with a resonant frequency between 50-200 kHz. use [math]L[/math] = 10 - 100 [math]\mu H[/math], R = 1k [math]\Omega[/math]

Construct the LC circuit using a non-polar capacitor

Measure the Gain [math]\equiv \frac{V_{out}}{V_{in}}[/math] as a function of frequency. (25 pnts)

Compare the measured and theoretical values of the resonance frequency ([math]\omega_{L}[/math]) (10 pnts)

Questions

The RLC cicuit

Design and construct a series LRC circuit

Measure and Graph the Gain as a function of the oscillating input voltage frequency. (25 pnts)

Measure and Graph the Phase Shift as a function of the oscillating input voltage frequency. (25 pnts)

Questions

What is the current [math]I[/math] at resonance? (5 pnts)

What is the current as [math]\nu \rightarrow \infty[/math]? (5 pnts)

Navigation menu

Search

Measure the Gain as a function of frequency. (25 pnts)